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BSFitter.cc
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1 
13 #include "Minuit2/VariableMetricMinimizer.h"
14 #include "Minuit2/FunctionMinimum.h"
15 #include "Minuit2/MnPrint.h"
16 #include "Minuit2/MnMigrad.h"
17 #include "Minuit2/MnUserParameterState.h"
18 //#include "CLHEP/config/CLHEP.h"
19 
20 // C++ standard
21 #include <vector>
22 #include <cmath>
23 
24 // CMS
29 
30 // ROOT
31 #include "TMatrixD.h"
32 #include "TMatrixDSym.h"
33 #include "TDecompBK.h"
34 #include "TH1.h"
35 #include "TF1.h"
36 #include "TMinuitMinimizer.h"
37 
38 using namespace ROOT::Minuit2;
39 
40 //_____________________________________________________________________
42  fbeamtype = reco::BeamSpot::Unknown;
43 
44  //In order to make fitting ROOT histograms thread safe
45  // one must call this undocumented function
46  TMinuitMinimizer::UseStaticMinuit(false);
47 }
48 
49 //_____________________________________________________________________
50 BSFitter::BSFitter(const std::vector<BSTrkParameters> &BSvector) {
51  //In order to make fitting ROOT histograms thread safe
52  // one must call this undocumented function
53  TMinuitMinimizer::UseStaticMinuit(false);
54 
55  ffit_type = "default";
56  ffit_variable = "default";
57 
58  fBSvector = BSvector;
59 
60  fsqrt2pi = sqrt(2. * TMath::Pi());
61 
62  fpar_name[0] = "z0 ";
63  fpar_name[1] = "SigmaZ0 ";
64  fpar_name[2] = "X0 ";
65  fpar_name[3] = "Y0 ";
66  fpar_name[4] = "dxdz ";
67  fpar_name[5] = "dydz ";
68  fpar_name[6] = "SigmaBeam ";
69 
70  //if (theGausszFcn == 0 ) {
71  thePDF = new BSpdfsFcn();
72 
73  //}
74  //if (theFitter == 0 ) {
75 
76  theFitter = new VariableMetricMinimizer();
77 
78  //}
79 
80  fapplyd0cut = false;
81  fapplychi2cut = false;
82  ftmprow = 0;
83  ftmp.ResizeTo(4, 1);
84  ftmp.Zero();
85  fnthite = 0;
86  fMaxZ = 50.; //cm
87  fconvergence = 0.5; // stop fit when 50% of the input collection has been removed.
88  fminNtrks = 100;
89  finputBeamWidth = -1; // no input
90 
91  h1z = new TH1F("h1z", "z distribution", 200, -fMaxZ, fMaxZ);
92 }
93 
94 //______________________________________________________________________
96  //delete fBSvector;
97  delete thePDF;
98  delete theFitter;
99 }
100 
101 //______________________________________________________________________
102 reco::BeamSpot BSFitter::Fit() { return this->Fit(nullptr); }
103 
104 //______________________________________________________________________
105 reco::BeamSpot BSFitter::Fit(double *inipar = nullptr) {
106  fbeamtype = reco::BeamSpot::Unknown;
107  if (ffit_variable == "z") {
108  if (ffit_type == "chi2") {
109  return Fit_z_chi2(inipar);
110 
111  } else if (ffit_type == "likelihood") {
112  return Fit_z_likelihood(inipar);
113 
114  } else if (ffit_type == "combined") {
115  reco::BeamSpot tmp_beamspot = Fit_z_chi2(inipar);
116  double tmp_par[2] = {tmp_beamspot.z0(), tmp_beamspot.sigmaZ()};
117  return Fit_z_likelihood(tmp_par);
118 
119  } else {
120  throw cms::Exception("LogicError")
121  << "Error in BeamSpotProducer/BSFitter: "
122  << "Illegal fit type, options are chi2,likelihood or combined(ie. first chi2 then likelihood)";
123  }
124  } else if (ffit_variable == "d") {
125  if (ffit_type == "d0phi") {
126  this->d0phi_Init();
127  return Fit_d0phi();
128 
129  } else if (ffit_type == "likelihood") {
130  return Fit_d_likelihood(inipar);
131 
132  } else if (ffit_type == "combined") {
133  this->d0phi_Init();
134  reco::BeamSpot tmp_beamspot = Fit_d0phi();
135  double tmp_par[4] = {tmp_beamspot.x0(), tmp_beamspot.y0(), tmp_beamspot.dxdz(), tmp_beamspot.dydz()};
136  return Fit_d_likelihood(tmp_par);
137 
138  } else {
139  throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: "
140  << "Illegal fit type, options are d0phi, likelihood or combined";
141  }
142  } else if (ffit_variable == "d*z" || ffit_variable == "default") {
143  if (ffit_type == "likelihood" || ffit_type == "default") {
145  // we are now fitting Z inside d0phi fitter
146  // first fit z distribution using a chi2 fit
147  //reco::BeamSpot tmp_z = Fit_z_chi2(inipar);
148  //for (int j = 2 ; j < 4 ; ++j) {
149  //for(int k = j ; k < 4 ; ++k) {
150  // matrix(j,k) = tmp_z.covariance()(j,k);
151  //}
152  //}
153 
154  // use d0-phi algorithm to extract transverse position
155  this->d0phi_Init();
156  //reco::BeamSpot tmp_d0phi= Fit_d0phi(); // change to iterative procedure:
157  this->Setd0Cut_d0phi(4.0);
158  reco::BeamSpot tmp_d0phi = Fit_ited0phi();
159 
160  //for (int j = 0 ; j < 2 ; ++j) {
161  // for(int k = j ; k < 2 ; ++k) {
162  // matrix(j,k) = tmp_d0phi.covariance()(j,k);
163  //}
164  //}
165  // slopes
166  //for (int j = 4 ; j < 6 ; ++j) {
167  // for(int k = j ; k < 6 ; ++k) {
168  // matrix(j,k) = tmp_d0phi.covariance()(j,k);
169  // }
170  //}
171 
172  // put everything into one object
173  reco::BeamSpot spot(reco::BeamSpot::Point(tmp_d0phi.x0(), tmp_d0phi.y0(), tmp_d0phi.z0()),
174  tmp_d0phi.sigmaZ(),
175  tmp_d0phi.dxdz(),
176  tmp_d0phi.dydz(),
177  0.,
178  tmp_d0phi.covariance(),
179  fbeamtype);
180 
181  //reco::BeamSpot tmp_z = Fit_z_chi2(inipar);
182 
183  //reco::BeamSpot tmp_d0phi = Fit_d0phi();
184 
185  // log-likelihood fit
186  if (ffit_type == "likelihood") {
187  double tmp_par[7] = {
188  tmp_d0phi.x0(), tmp_d0phi.y0(), tmp_d0phi.z0(), tmp_d0phi.sigmaZ(), tmp_d0phi.dxdz(), tmp_d0phi.dydz(), 0.0};
189 
190  double tmp_error_par[7];
191  for (int s = 0; s < 6; s++) {
192  tmp_error_par[s] = pow(tmp_d0phi.covariance()(s, s), 0.5);
193  }
194  tmp_error_par[6] = 0.0;
195 
196  reco::BeamSpot tmp_lh = Fit_d_z_likelihood(tmp_par, tmp_error_par);
197 
198  if (edm::isNotFinite(ff_minimum)) {
199  edm::LogWarning("BSFitter")
200  << "BSFitter: Result is non physical. Log-Likelihood fit to extract beam width did not converge."
201  << std::endl;
203  return tmp_lh;
204  }
205  return tmp_lh;
206 
207  } else {
208  edm::LogInfo("BSFitter") << "default track-based fit does not extract beam width." << std::endl;
209  return spot;
210  }
211 
212  } else if (ffit_type == "resolution") {
213  reco::BeamSpot tmp_z = Fit_z_chi2(inipar);
214  this->d0phi_Init();
215  reco::BeamSpot tmp_d0phi = Fit_d0phi();
216 
217  double tmp_par[7] = {
218  tmp_d0phi.x0(), tmp_d0phi.y0(), tmp_z.z0(), tmp_z.sigmaZ(), tmp_d0phi.dxdz(), tmp_d0phi.dydz(), 0.0};
219  double tmp_error_par[7];
220  for (int s = 0; s < 6; s++) {
221  tmp_error_par[s] = pow(tmp_par[s], 0.5);
222  }
223  tmp_error_par[6] = 0.0;
224 
225  reco::BeamSpot tmp_beam = Fit_d_z_likelihood(tmp_par, tmp_error_par);
226 
227  double tmp_par2[7] = {tmp_beam.x0(),
228  tmp_beam.y0(),
229  tmp_beam.z0(),
230  tmp_beam.sigmaZ(),
231  tmp_beam.dxdz(),
232  tmp_beam.dydz(),
233  tmp_beam.BeamWidthX()};
234 
235  reco::BeamSpot tmp_lh = Fit_dres_z_likelihood(tmp_par2);
236 
237  if (edm::isNotFinite(ff_minimum)) {
238  edm::LogWarning("BSFitter") << "Result is non physical. Log-Likelihood fit did not converge." << std::endl;
240  return tmp_lh;
241  }
242  return tmp_lh;
243 
244  } else {
245  throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: "
246  << "Illegal fit type, options are likelihood or resolution";
247  }
248  } else {
249  throw cms::Exception("LogicError") << "Error in BeamSpotProducer/BSFitter: "
250  << "Illegal variable type, options are \"z\", \"d\", or \"d*z\"";
251  }
252 }
253 
254 //______________________________________________________________________
256  //std::cout << "Fit_z(double *) called" << std::endl;
257  //std::cout << "inipar[0]= " << inipar[0] << std::endl;
258  //std::cout << "inipar[1]= " << inipar[1] << std::endl;
259 
260  std::vector<double> par(2, 0);
261  std::vector<double> err(2, 0);
262 
263  par.push_back(0.0);
264  par.push_back(7.0);
265  err.push_back(0.0001);
266  err.push_back(0.0001);
267  //par[0] = 0.0; err[0] = 0.0;
268  //par[1] = 7.0; err[1] = 0.0;
269 
270  thePDF->SetPDFs("PDFGauss_z");
271  thePDF->SetData(fBSvector);
272  //std::cout << "data loaded"<< std::endl;
273 
274  //FunctionMinimum fmin = theFitter->Minimize(*theGausszFcn, par, err, 1, 500, 0.1);
275  MnUserParameters upar;
276  upar.Add("X0", 0., 0.);
277  upar.Add("Y0", 0., 0.);
278  upar.Add("Z0", inipar[0], 0.001);
279  upar.Add("sigmaZ", inipar[1], 0.001);
280 
281  MnMigrad migrad(*thePDF, upar);
282 
283  FunctionMinimum fmin = migrad();
284  ff_minimum = fmin.Fval();
285  //std::cout << " eval= " << ff_minimum
286  // << "/n params[0]= " << fmin.Parameters().Vec()(0) << std::endl;
287 
288  /*
289  TMinuit *gmMinuit = new TMinuit(2);
290 
291  //gmMinuit->SetFCN(z_fcn);
292  gmMinuit->SetFCN(myFitz_fcn);
293 
294 
295  int ierflg = 0;
296  double step[2] = {0.001,0.001};
297 
298  for (int i = 0; i<2; i++) {
299  gmMinuit->mnparm(i,fpar_name[i].c_str(),inipar[i],step[i],0,0,ierflg);
300  }
301  gmMinuit->Migrad();
302  */
304 
305  for (int j = 2; j < 4; ++j) {
306  for (int k = j; k < 4; ++k) {
307  matrix(j, k) = fmin.Error().Matrix()(j, k);
308  }
309  }
310 
311  return reco::BeamSpot(reco::BeamSpot::Point(0., 0., fmin.Parameters().Vec()(2)),
312  fmin.Parameters().Vec()(3),
313  0.,
314  0.,
315  0.,
316  matrix,
317  fbeamtype);
318 }
319 
320 //______________________________________________________________________
322  // N.B. this fit is not performed anymore but now
323  // Z is fitted in the same track set used in the d0-phi fit after
324  // each iteration
325 
326  //std::cout << "Fit_z_chi2() called" << std::endl;
327  // FIXME: include whole tracker z length for the time being
328  // ==> add protection and z0 cut
329  h1z = new TH1F("h1z", "z distribution", 200, -fMaxZ, fMaxZ);
330 
331  std::vector<BSTrkParameters>::const_iterator iparam = fBSvector.begin();
332 
333  // HERE check size of track vector
334 
335  for (iparam = fBSvector.begin(); iparam != fBSvector.end(); ++iparam) {
336  h1z->Fill(iparam->z0());
337  //std::cout<<"z0="<<iparam->z0()<<"; sigZ0="<<iparam->sigz0()<<std::endl;
338  }
339 
340  //Use our own copy for thread safety
341  // also do not add to global list of functions
342  TF1 fgaus("fgaus", "gaus", 0., 1., TF1::EAddToList::kNo);
343  h1z->Fit(&fgaus, "QLMN0 SERIAL");
344  //std::cout << "fitted "<< std::endl;
345 
346  //std::cout << "got function" << std::endl;
347  double fpar[2] = {fgaus.GetParameter(1), fgaus.GetParameter(2)};
348  //std::cout<<"Debug fpar[2] = (" <<fpar[0]<<","<<fpar[1]<<")"<<std::endl;
350  // add matrix values.
351  matrix(2, 2) = fgaus.GetParError(1) * fgaus.GetParError(1);
352  matrix(3, 3) = fgaus.GetParError(2) * fgaus.GetParError(2);
353 
354  //delete h1z;
355 
356  return reco::BeamSpot(reco::BeamSpot::Point(0., 0., fpar[0]), fpar[1], 0., 0., 0., matrix, fbeamtype);
357 }
358 
359 //______________________________________________________________________
361  this->d0phi_Init();
362  edm::LogInfo("BSFitter") << "number of total input tracks: " << fBSvector.size() << std::endl;
363 
364  reco::BeamSpot theanswer;
365 
366  if ((int)fBSvector.size() <= fminNtrks) {
367  edm::LogWarning("BSFitter") << "need at least " << fminNtrks << " tracks to run beamline fitter." << std::endl;
368  fbeamtype = reco::BeamSpot::Fake;
369  theanswer.setType(fbeamtype);
370  return theanswer;
371  }
372 
373  theanswer = Fit_d0phi(); //get initial ftmp and ftmprow
374  if (goodfit)
375  fnthite++;
376  //std::cout << "Initial tempanswer (iteration 0): " << theanswer << std::endl;
377 
378  reco::BeamSpot preanswer = theanswer;
379 
380  while (goodfit && ftmprow > fconvergence * fBSvector.size() && ftmprow > fminNtrks) {
381  theanswer = Fit_d0phi();
382  fd0cut /= 1.5;
383  fchi2cut /= 1.5;
384  if (goodfit && ftmprow > fconvergence * fBSvector.size() && ftmprow > fminNtrks) {
385  preanswer = theanswer;
386  //std::cout << "Iteration " << fnthite << ": " << preanswer << std::endl;
387  fnthite++;
388  }
389  }
390  // FIXME: return fit results from previous iteration for both bad fit and for >50% tracks thrown away
391  //std::cout << "The last iteration, theanswer: " << theanswer << std::endl;
392  theanswer = preanswer;
393  //std::cout << "Use previous results from iteration #" << ( fnthite > 0 ? fnthite-1 : 0 ) << std::endl;
394  //if ( fnthite > 1 ) std::cout << theanswer << std::endl;
395 
396  edm::LogInfo("BSFitter") << "Total number of successful iterations = " << (goodfit ? (fnthite + 1) : fnthite)
397  << std::endl;
398  if (goodfit) {
399  fbeamtype = reco::BeamSpot::Tracker;
400  theanswer.setType(fbeamtype);
401  } else {
402  edm::LogWarning("BSFitter") << "Fit doesn't converge!!!" << std::endl;
403  fbeamtype = reco::BeamSpot::Unknown;
404  theanswer.setType(fbeamtype);
405  }
406  return theanswer;
407 }
408 
409 //______________________________________________________________________
411  //LogDebug ("BSFitter") << " we will use " << fBSvector.size() << " tracks.";
412  if (fnthite > 0)
413  edm::LogInfo("BSFitter") << " number of tracks used: " << ftmprow << std::endl;
414  //std::cout << " ftmp = matrix("<<ftmp.GetNrows()<<","<<ftmp.GetNcols()<<")"<<std::endl;
415  //std::cout << " ftmp(0,0)="<<ftmp(0,0)<<std::endl;
416  //std::cout << " ftmp(1,0)="<<ftmp(1,0)<<std::endl;
417  //std::cout << " ftmp(2,0)="<<ftmp(2,0)<<std::endl;
418  //std::cout << " ftmp(3,0)="<<ftmp(3,0)<<std::endl;
419 
420  h1z->Reset();
421 
422  TMatrixD x_result(4, 1);
423  TMatrixDSym V_result(4);
424 
425  TMatrixDSym Vint(4);
426  TMatrixD b(4, 1);
427 
428  //Double_t weightsum = 0;
429 
430  Vint.Zero();
431  b.Zero();
432 
433  TMatrixD g(4, 1);
434  TMatrixDSym temp(4);
435 
436  std::vector<BSTrkParameters>::iterator iparam = fBSvector.begin();
437  ftmprow = 0;
438 
439  //edm::LogInfo ("BSFitter") << " test";
440 
441  //std::cout << "BSFitter: fit" << std::endl;
442 
443  for (iparam = fBSvector.begin(); iparam != fBSvector.end(); ++iparam) {
444  //if(i->weight2 == 0) continue;
445 
446  //if (ftmprow==0) {
447  //std::cout << "d0=" << iparam->d0() << " sigd0=" << iparam->sigd0()
448  //<< " phi0="<< iparam->phi0() << " z0=" << iparam->z0() << std::endl;
449  //std::cout << "d0phi_d0=" << iparam->d0phi_d0() << " d0phi_chi2="<<iparam->d0phi_chi2() << std::endl;
450  //}
451  g(0, 0) = sin(iparam->phi0());
452  g(1, 0) = -cos(iparam->phi0());
453  g(2, 0) = iparam->z0() * g(0, 0);
454  g(3, 0) = iparam->z0() * g(1, 0);
455 
456  // average transverse beam width
457  double sigmabeam2 = 0.006 * 0.006;
458  if (finputBeamWidth > 0)
459  sigmabeam2 = finputBeamWidth * finputBeamWidth;
460  else {
461  //edm::LogWarning("BSFitter") << "using in fit beam width = " << sqrt(sigmabeam2) << std::endl;
462  }
463 
464  //double sigma2 = sigmabeam2 + (iparam->sigd0())* (iparam->sigd0()) / iparam->weight2;
465  // this should be 2*sigmabeam2?
466  double sigma2 = sigmabeam2 + (iparam->sigd0()) * (iparam->sigd0());
467 
468  TMatrixD ftmptrans(1, 4);
469  ftmptrans = ftmptrans.Transpose(ftmp);
470  TMatrixD dcor = ftmptrans * g;
471  double chi2tmp = (iparam->d0() - dcor(0, 0)) * (iparam->d0() - dcor(0, 0)) / sigma2;
472  (*iparam) = BSTrkParameters(
473  iparam->z0(), iparam->sigz0(), iparam->d0(), iparam->sigd0(), iparam->phi0(), iparam->pt(), dcor(0, 0), chi2tmp);
474 
475  bool pass = true;
476  if (fapplyd0cut && fnthite > 0) {
477  if (std::abs(iparam->d0() - dcor(0, 0)) > fd0cut)
478  pass = false;
479  }
480  if (fapplychi2cut && fnthite > 0) {
481  if (chi2tmp > fchi2cut)
482  pass = false;
483  }
484 
485  if (pass) {
486  temp.Zero();
487  for (int j = 0; j < 4; ++j) {
488  for (int k = j; k < 4; ++k) {
489  temp(j, k) += g(j, 0) * g(k, 0);
490  }
491  }
492 
493  Vint += (temp * (1 / sigma2));
494  b += (iparam->d0() / sigma2 * g);
495  //weightsum += sqrt(i->weight2);
496  ftmprow++;
497  h1z->Fill(iparam->z0());
498  }
499  }
500  Double_t determinant;
501  TDecompBK bk(Vint);
502  bk.SetTol(1e-11); //FIXME: find a better way to solve x_result
503  if (!bk.Decompose()) {
504  goodfit = false;
505  edm::LogWarning("BSFitter") << "Decomposition failed, matrix singular ?" << std::endl
506  << "condition number = " << bk.Condition() << std::endl;
507  } else {
508  V_result = Vint.InvertFast(&determinant);
509  x_result = V_result * b;
510  }
511  // for(int j = 0 ; j < 4 ; ++j) {
512  // for(int k = 0 ; k < 4 ; ++k) {
513  // std::cout<<"V_result("<<j<<","<<k<<")="<<V_result(j,k)<<std::endl;
514  // }
515  // }
516  // for (int j=0;j<4;++j){
517  // std::cout<<"x_result("<<j<<",0)="<<x_result(j,0)<<std::endl;
518  // }
519  //LogDebug ("BSFitter") << " d0-phi fit done.";
520  //std::cout<< " d0-phi fit done." << std::endl;
521 
522  //Use our own copy for thread safety
523  // also do not add to global list of functions
524  TF1 fgaus("fgaus", "gaus", 0., 1., TF1::EAddToList::kNo);
525  //returns 0 if OK
526  //auto status = h1z->Fit(&fgaus,"QLM0","",h1z->GetMean() -2.*h1z->GetRMS(),h1z->GetMean() +2.*h1z->GetRMS());
527  auto status =
528  h1z->Fit(&fgaus, "QLN0 SERIAL", "", h1z->GetMean() - 2. * h1z->GetRMS(), h1z->GetMean() + 2. * h1z->GetRMS());
529 
530  //std::cout << "fitted "<< std::endl;
531 
532  //std::cout << "got function" << std::endl;
533  if (status) {
534  //edm::LogError("NoBeamSpotFit")<<"gaussian fit failed. no BS d0 fit";
535 
536  goodfit = false;
537  return reco::BeamSpot();
538  }
539  double fpar[2] = {fgaus.GetParameter(1), fgaus.GetParameter(2)};
540 
542  // first two parameters
543  for (int j = 0; j < 2; ++j) {
544  for (int k = j; k < 2; ++k) {
545  matrix(j, k) = V_result(j, k);
546  }
547  }
548  // slope parameters
549  for (int j = 4; j < 6; ++j) {
550  for (int k = j; k < 6; ++k) {
551  matrix(j, k) = V_result(j - 2, k - 2);
552  }
553  }
554 
555  // Z0 and sigmaZ
556  matrix(2, 2) = fgaus.GetParError(1) * fgaus.GetParError(1);
557  matrix(3, 3) = fgaus.GetParError(2) * fgaus.GetParError(2);
558 
559  ftmp = x_result;
560 
561  // x0 and y0 are *not* x,y at z=0, but actually at z=0
562  // to correct for this, we need to translate them to z=z0
563  // using the measured slopes
564  //
565  double x0tmp = x_result(0, 0);
566  double y0tmp = x_result(1, 0);
567 
568  x0tmp += x_result(2, 0) * fpar[0];
569  y0tmp += x_result(3, 0) * fpar[0];
570 
571  return reco::BeamSpot(
572  reco::BeamSpot::Point(x0tmp, y0tmp, fpar[0]), fpar[1], x_result(2, 0), x_result(3, 0), 0., matrix, fbeamtype);
573 }
574 
575 //______________________________________________________________________
576 void BSFitter::Setd0Cut_d0phi(double d0cut) {
577  fapplyd0cut = true;
578 
579  //fBSforCuts = BSfitted;
580  fd0cut = d0cut;
581 }
582 
583 //______________________________________________________________________
585  fapplychi2cut = true;
586 
587  //fBSforCuts = BSfitted;
588  fchi2cut = chi2cut;
589 }
590 
591 //______________________________________________________________________
593  thePDF->SetPDFs("PDFGauss_d");
594  thePDF->SetData(fBSvector);
595 
596  MnUserParameters upar;
597  upar.Add("X0", inipar[0], 0.001);
598  upar.Add("Y0", inipar[1], 0.001);
599  upar.Add("Z0", 0., 0.001);
600  upar.Add("sigmaZ", 0., 0.001);
601  upar.Add("dxdz", inipar[2], 0.001);
602  upar.Add("dydz", inipar[3], 0.001);
603 
604  MnMigrad migrad(*thePDF, upar);
605 
606  FunctionMinimum fmin = migrad();
607  ff_minimum = fmin.Fval();
608 
610  for (int j = 0; j < 6; ++j) {
611  for (int k = j; k < 6; ++k) {
612  matrix(j, k) = fmin.Error().Matrix()(j, k);
613  }
614  }
615 
616  return reco::BeamSpot(reco::BeamSpot::Point(fmin.Parameters().Vec()(0), fmin.Parameters().Vec()(1), 0.),
617  0.,
618  fmin.Parameters().Vec()(4),
619  fmin.Parameters().Vec()(5),
620  0.,
621  matrix,
622  fbeamtype);
623 }
624 //______________________________________________________________________
625 double BSFitter::scanPDF(double *init_pars, int &tracksfixed, int option) {
626  if (option == 1)
627  init_pars[6] = 0.0005; //starting value for any given configuration
628 
629  //local vairables with initial values
630  double fsqrt2pi = 0.0;
631  double d_sig = 0.0;
632  double d_dprime = 0.0;
633  double d_result = 0.0;
634  double z_sig = 0.0;
635  double z_result = 0.0;
636  double function = 0.0;
637  double tot_pdf = 0.0;
638  double last_minvalue = 1.0e+10;
639  double init_bw = -99.99;
640  int iters = 0;
641 
642  //used to remove tracks if far away from bs by this
643  double DeltadCut = 0.1000;
644  if (init_pars[6] < 0.0200) {
645  DeltadCut = 0.0900;
646  } //worked for high 2.36TeV
647  if (init_pars[6] < 0.0100) {
648  DeltadCut = 0.0700;
649  } //just a guesss for 7 TeV but one should scan for actual values
650 
651  std::vector<BSTrkParameters>::const_iterator iparam = fBSvector.begin();
652 
653  if (option == 1)
654  iters = 500;
655  if (option == 2)
656  iters = 1;
657 
658  for (int p = 0; p < iters; p++) {
659  if (iters == 500)
660  init_pars[6] += 0.0002;
661  tracksfixed = 0;
662 
663  for (iparam = fBSvector.begin(); iparam != fBSvector.end(); ++iparam) {
664  fsqrt2pi = sqrt(2. * TMath::Pi());
665  d_sig = sqrt(init_pars[6] * init_pars[6] + (iparam->sigd0()) * (iparam->sigd0()));
666  d_dprime = iparam->d0() - (((init_pars[0] + iparam->z0() * (init_pars[4])) * sin(iparam->phi0())) -
667  ((init_pars[1] + iparam->z0() * (init_pars[5])) * cos(iparam->phi0())));
668 
669  //***Remove tracks before the fit which gives low pdf values to blow up the pdf
670  if (std::abs(d_dprime) < DeltadCut && option == 2) {
671  fBSvectorBW.push_back(*iparam);
672  }
673 
674  d_result = (exp(-(d_dprime * d_dprime) / (2.0 * d_sig * d_sig))) / (d_sig * fsqrt2pi);
675  z_sig = sqrt(iparam->sigz0() * iparam->sigz0() + init_pars[3] * init_pars[3]);
676  z_result = (exp(-((iparam->z0() - init_pars[2]) * (iparam->z0() - init_pars[2])) / (2.0 * z_sig * z_sig))) /
677  (z_sig * fsqrt2pi);
678  tot_pdf = z_result * d_result;
679 
680  //for those trcks which gives problems due to very tiny pdf_d values.
681  //Update: This protection will NOT be used with the dprime cut above but still kept here to get
682  // the intial value of beam width reasonably
683  //A warning will appear if there were any tracks with < 10^-5 for pdf_d so that (d-dprime) cut can be lowered
684  if (d_result < 1.0e-05) {
685  tot_pdf = z_result * 1.0e-05;
686  //if(option==2)std::cout<<"last Iter d-d' = "<<(std::abs(d_dprime))<<std::endl;
687  tracksfixed++;
688  }
689 
690  function = function + log(tot_pdf);
691 
692  } //loop over tracks
693 
694  function = -2.0 * function;
695  if (function < last_minvalue) {
696  init_bw = init_pars[6];
697  last_minvalue = function;
698  }
699  function = 0.0;
700  } //loop over beam width
701 
702  if (init_bw > 0) {
703  init_bw = init_bw + (0.20 * init_bw); //start with 20 % more
704 
705  } else {
706  if (option == 1) {
707  edm::LogWarning("BSFitter")
708  << "scanPDF:====>>>> WARNING***: The initial guess value of Beam width is negative!!!!!!" << std::endl
709  << "scanPDF:====>>>> Assigning beam width a starting value of " << init_bw << " cm" << std::endl;
710  init_bw = 0.0200;
711  }
712  }
713 
714  return init_bw;
715 }
716 
717 //________________________________________________________________________________
718 reco::BeamSpot BSFitter::Fit_d_z_likelihood(double *inipar, double *error_par) {
719  int tracksFailed = 0;
720 
721  //estimate first guess of beam width and tame 20% extra of it to start
722  inipar[6] = scanPDF(inipar, tracksFailed, 1);
723  error_par[6] = (inipar[6]) * 0.20;
724 
725  //Here remove the tracks which give low pdf and fill into a new vector
726  //std::cout<<"Size of Old vector = "<<(fBSvector.size())<<std::endl;
727  /* double junk= */ scanPDF(inipar, tracksFailed, 2);
728  //std::cout<<"Size of New vector = "<<(fBSvectorBW.size())<<std::endl;
729 
730  //Refill the fBSVector again with new sets of tracks
731  fBSvector.clear();
732  std::vector<BSTrkParameters>::const_iterator iparamBW = fBSvectorBW.begin();
733  for (iparamBW = fBSvectorBW.begin(); iparamBW != fBSvectorBW.end(); ++iparamBW) {
734  fBSvector.push_back(*iparamBW);
735  }
736 
737  thePDF->SetPDFs("PDFGauss_d*PDFGauss_z");
738  thePDF->SetData(fBSvector);
739  MnUserParameters upar;
740 
741  upar.Add("X0", inipar[0], error_par[0]);
742  upar.Add("Y0", inipar[1], error_par[1]);
743  upar.Add("Z0", inipar[2], error_par[2]);
744  upar.Add("sigmaZ", inipar[3], error_par[3]);
745  upar.Add("dxdz", inipar[4], error_par[4]);
746  upar.Add("dydz", inipar[5], error_par[5]);
747  upar.Add("BeamWidthX", inipar[6], error_par[6]);
748 
749  MnMigrad migrad(*thePDF, upar);
750 
751  FunctionMinimum fmin = migrad();
752 
753  // std::cout<<"-----how the fit evoves------"<<std::endl;
754  // std::cout<<fmin<<std::endl;
755 
756  ff_minimum = fmin.Fval();
757 
758  bool ff_nfcn = fmin.HasReachedCallLimit();
759  bool ff_cov = fmin.HasCovariance();
760  bool testing = fmin.IsValid();
761 
762  //Print WARNINGS if minimum did not converged
763  if (!testing) {
764  edm::LogWarning("BSFitter") << "===========>>>>>** WARNING: MINUIT DID NOT CONVERGES PROPERLY !!!!!!" << std::endl;
765  if (ff_nfcn)
766  edm::LogWarning("BSFitter") << "===========>>>>>** WARNING: No. of Calls Exhausted" << std::endl;
767  if (!ff_cov)
768  edm::LogWarning("BSFitter") << "===========>>>>>** WARNING: Covariance did not found" << std::endl;
769  }
770 
771  edm::LogInfo("BSFitter") << "The Total # Tracks used for beam width fit = " << (fBSvectorBW.size()) << std::endl;
772 
773  //Checks after fit is performed
774  double lastIter_pars[7];
775 
776  for (int ip = 0; ip < 7; ip++) {
777  lastIter_pars[ip] = fmin.Parameters().Vec()(ip);
778  }
779 
780  tracksFailed = 0;
781  /* double lastIter_scan= */ scanPDF(lastIter_pars, tracksFailed, 2);
782 
783  edm::LogWarning("BSFitter") << "WARNING: # of tracks which have very low pdf value (pdf_d < 1.0e-05) are = "
784  << tracksFailed << std::endl;
785 
786  //std::cout << " eval= " << ff_minimum
787  // << "/n params[0]= " << fmin.Parameters().Vec()(0) << std::endl;
788 
790 
791  for (int j = 0; j < 7; ++j) {
792  for (int k = j; k < 7; ++k) {
793  matrix(j, k) = fmin.Error().Matrix()(j, k);
794  }
795  }
796 
797  return reco::BeamSpot(
798  reco::BeamSpot::Point(fmin.Parameters().Vec()(0), fmin.Parameters().Vec()(1), fmin.Parameters().Vec()(2)),
799  fmin.Parameters().Vec()(3),
800  fmin.Parameters().Vec()(4),
801  fmin.Parameters().Vec()(5),
802  fmin.Parameters().Vec()(6),
803 
804  matrix,
805  fbeamtype);
806 }
807 
808 //______________________________________________________________________
810  thePDF->SetPDFs("PDFGauss_d_resolution*PDFGauss_z");
811  thePDF->SetData(fBSvector);
812 
813  MnUserParameters upar;
814  upar.Add("X0", inipar[0], 0.001);
815  upar.Add("Y0", inipar[1], 0.001);
816  upar.Add("Z0", inipar[2], 0.001);
817  upar.Add("sigmaZ", inipar[3], 0.001);
818  upar.Add("dxdz", inipar[4], 0.001);
819  upar.Add("dydz", inipar[5], 0.001);
820  upar.Add("BeamWidthX", inipar[6], 0.0001);
821  upar.Add("c0", 0.0010, 0.0001);
822  upar.Add("c1", 0.0090, 0.0001);
823 
824  // fix beam width
825  upar.Fix("BeamWidthX");
826  // number of parameters in fit are 9-1 = 8
827 
828  MnMigrad migrad(*thePDF, upar);
829 
830  FunctionMinimum fmin = migrad();
831  ff_minimum = fmin.Fval();
832 
834 
835  for (int j = 0; j < 6; ++j) {
836  for (int k = j; k < 6; ++k) {
837  matrix(j, k) = fmin.Error().Matrix()(j, k);
838  }
839  }
840 
841  //std::cout << " fill resolution values" << std::endl;
842  //std::cout << " matrix size= " << fmin.Error().Matrix().size() << std::endl;
843  //std::cout << " vec(6)="<< fmin.Parameters().Vec()(6) << std::endl;
844  //std::cout << " vec(7)="<< fmin.Parameters().Vec()(7) << std::endl;
845 
846  fresolution_c0 = fmin.Parameters().Vec()(6);
847  fresolution_c1 = fmin.Parameters().Vec()(7);
848  fres_c0_err = sqrt(fmin.Error().Matrix()(6, 6));
849  fres_c1_err = sqrt(fmin.Error().Matrix()(7, 7));
850 
851  for (int j = 6; j < 8; ++j) {
852  for (int k = 6; k < 8; ++k) {
853  fres_matrix(j - 6, k - 6) = fmin.Error().Matrix()(j, k);
854  }
855  }
856 
857  return reco::BeamSpot(
858  reco::BeamSpot::Point(fmin.Parameters().Vec()(0), fmin.Parameters().Vec()(1), fmin.Parameters().Vec()(2)),
859  fmin.Parameters().Vec()(3),
860  fmin.Parameters().Vec()(4),
861  fmin.Parameters().Vec()(5),
862  inipar[6],
863  matrix,
864  fbeamtype);
865 }
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